工31讲绰第麵482號專利說明書、申請專利範圍及圖式修正本。 L,發明說明: f發明所屬之技術領域】 本發明係關於-種微型散熱模組,特別是關於在一微 燊散熱基板上設置至少二定位部,藉由該定位部將一微型 麟熱風掣穩_結合於該微·熱基板上之微型散敎 f先前技術】 習用散熱模組,請參照第!圖所示,其包含一散熱基 板7、數個固^元件8及-散熱風扇9。該散熱基板7之一 表面設有數個散熱鰭片71及數個散熱槽道72,各該散熱 糟道72係形成於該各相鄰之散熱鰭片71之間。另外,詨 散熱槽道72之底面形成有數個級裝孔乃,以供該固定元 件8對應穿設定位。該固定元件8設有一扣合部、一抵 樓肩部82及一復位彈簧83。該扣合部81形^該固^ 件8之一端,其係選自一倒錐狀構造,且於該扣合部μ 中央開設一切口〔未標示〕,進而提供一彈性變形空間。 該抵撐肩部82形成於該固定元件8之另一端。該復位彈! 83對應套設於㈣定元件8上,其—端係抵靠於該抵撐= 部82。該散熱風扇9之角隅位置係對應該組裝孔73設有 數個通孔91。 當組裝該散熱風扇9於該散熱基板7上時,首先係將 5亥散熱風扇9之各通孔91分別對位於該散熱基板7之纟且♦ 孔73,接著該固定元件8之扣合部81藉由倒錐狀及該^ 口對應彈性迫入該通孔91内,直到該扣合部81通過該通 ~ 5 — 1314033 97.11.19第96102482號專利說明書、申請專利範圍及圓式修正本。 孔91及組裝孔73後,該扣合部81則立刻彈性復位恢復其 原本之外位’並經由該扣合部幻之底端卡擎於該散熱基板 7之底面。此時’該岐元件8之復位彈簧83健生一彈 性復位偏壓,使得該扣合部81之底端穩固的抵 •基板7之底面。藉此,利用該散熱風扇9驅離該散熱槽道 72内的熱氣,提升該散熱基板7之散熱效率。 一般而言,該散熱模組常應用於一電子裝置〔未繪示 ,例如:電腦晶片或微處理器等〕上。隨著科技日新月異 ,該電子裝置之尺寸致力朝向微小化發展,使得該電子裝 置越來越精密且微小。如此一來,導致該散熱模組之尺寸 及體積亦必須進-步相對微小化。然而。上述習用散熱模 組具有下列缺點,例如:習用散熱模組必須藉由分別設置 該固定元件8及_孔73,方可達成穩固定位之功效。但 該散熱模組之尺寸微小到一定程度時,係不容易在該散熱 基板7上開設足以容納該固定元件8之組裝孔7 3,亦難以 對應製造微小尺寸之固定元件8,導致習用散熱模組難以 應用於該微小化之電子裝置上。基於上述原因,有必要進 一步改良上述習用散熱模組。 * 有鑑於此,本發明改良上述之缺點,其係藉由在一微 • 魏熱基板上形成至少二放部,並姻該定位部將一微 型驅熱風機穩固的夾壓定位於該微型散熱基板上。另外, 該微型驅熱風機之一扇輪的旋轉面積係小於1.6 cm2〔平 方公分〕,進而縮小該微型散熱模組之尺寸,藉此本發明 確實可應用於微型化之電子裝置上,並具有簡化組褒構件 ㈣.作第郎_2號專利說明書、t請專利範_式修正本。 及提升組裝效率之功效。 【發明内容】 本發明之主要目的係提供一種微型散熱模組,其係藉 由在一微型散熱基板上形成至少二定位部,並利用該定位 部將-微型驅熱風機夾掣穩固的結合於該微型散熱基板上 ,而不需藉由設置任何組裝元件,使得本發明具有簡化組 裝構件及提升組裝可靠度、品質之功效。 本發明之次要目的係提供-種微型散熱模組,其中一 微型驅熱風機之-扇輪的旋轉面積小於16 cm2〔平方公 分〕,進而縮小該微型散熱模組之尺寸,使得本發明具有 應用於微型化產品的功效。 根據本發明之微型散熱模組,其包含一微型散熱基板 及一微型驅熱風機。該微型散熱基板具有一定位空間、一 氣流通道、數個散熱鰭片及至少二定位部,該定位空間、 氣流通道’散熱鰭片及定位部係均設置於該微型散熱基板 之-表面上,職流通道形成於該二相鄰的散熱鯖片之間 ,該氣流通道具有二端且沿平行該表面的方向由一端延伸 至另一端,且該數個散熱鰭片與該定位空間鄰接之一端共 同構成該至少二定位部之其中一個,且該定位空間形成於 該微型散熱基板之至少二定位部之間。該微型驅熱風機設 有一出風口、一入風口及一扇輪,該扇輪之旋轉面積小於 1.6平方公分’藉由該微型散熱基板之定位部將該微型驅熱 風機夹掣結合於該微型散熱基板之定位空間内,且選擇該 出風口及入風口之一對齊、朝向且緊接該散熱鰭片所構^ 第96102482號專利說明書、申請專利範圍及圖式修正本。 之定位部及該氣流通道與該定位空間鄰接之一端。 【實施方式】 為讓本發明之上述及其他目的、特徵及優點能更明顯 易懂’下文特舉本發明之較佳實施例,並配合所附圖式, 作詳細說明如下: 請參照第2圖所示,本發明第一實施例之微型散熱模 組係包含一微型散熱基板1及一微型驅熱風機2,該微型 驅熱風機2對應定位於該微型散熱基板1上,以形成一微 型散熱模組〔未標示〕。 請再參照第2圖所示,本發明第一實施例之微型散熱 基板1係由具高導熱能力之金屬或合金所製成,例如鋁、 銅、金、銀或其合金等,且該微型散熱基板丨較佳略具有 可撓性。該微型散熱基板1設有數個散熱鰭片u、至少一 氣流通道12、至少二定位部及一定位空間17,該散熱鰭片 11係對應該定位空間17凸設排列於該微型散熱基板i之 一表面’且各該氣流通道12形成於該各二相鄰的散熱鰭片 11之間。該散熱鰭片1丨、氣流通道12、定位部及定位空 間Π係均設置於該微型散熱基板丨之一表面上。該散熱鰭 片11及氣流通道12係用以增加該微型散熱基板丨之熱交 換面積,以快速驅散該微型散熱基板i所吸收之熱能,提 升散熱效率。 另外,本發明第一實施例之微型散熱基板1設有一第 -定位部13、-第二定位部14及—第三定位部15,各該 散熱縛片11之-侧邊係共同構成—阻擔面,進而作為該第 1314033 37_11.19第96102482號專利說明書、申請專利範圍及圖式修正本。 一定位部13。該最外側之二散熱鰭片u的一端係分別沿 著該微型散熱基板1之侧邊延伸形成該第二及第三定位部 14、15,且該第二及第三定位部14、15之頂部亦分別相向 朝内彎折形成一夾持片141、151。該定位空間17係形成 於該第一、第二、第三定位部13、14、15與該夾持片hi 、151之間。 請再參照第2圖所示’本發明第一實施例之微型驅熱 風機2係可選自一軸向入風且徑向出風之鼓風式驅熱風機 及一轴向入風且軸向出風之轴流式驅熱風機,本實施例之 微型驅熱風機2選擇為一軸向入風且徑向出風之鼓風式驅 熱風機。該微型驅熱風機2設有一殼體20、一入風口 21 、一出風口 22及一扇輪23。該殼體20内部具有一容置空 間〔未標示〕。該入風口 21係選擇轴向開設於該殼體2〇 之頂部;該出風口 22則選擇徑向開設於該殼體20之一側 面,且該出風口 22對應朝向該氣流通道12之一端。該扇 輪23可轉動的設置於該容置空間内,且其旋轉面積係選擇 小於1.6cm2〔平方公分〕,以便縮小該微型散熱模組之尺 寸’進一步使該微型散熱模組應用於一微型電子裝置〔例 如:微型電腦、微型PDA及手機等〕上。 • 請再參照第2圖所示,當本發明第一實施例進行組裝 時’首先係藉由該微型散熱基板1具有之可撓性,使得該 微型驅熱風機2得以沿著該微型散熱基板1之第二、第三 定位部14、15及夾持片141、151的内壁面迫入該定位空 間17内。由於該定位空間17之寬度及高度略小於該微型 —9 — 131魏 第96102482號專利說明書、申請專利範圍及圖式修正本 驅熱風機2之寬度及高度,以致該微型驅熱風機2被迫入 該定位空間17後,除了藉由該微型驅熱風機2之一端抵靠 於該第一定位部13,同時該第二、第三定位部14、15及 夹持片141、151亦穩固的將該微型驅熱風機2夾壓定位於 該定位空間17内,避免該微型驅熱風機2任意脫離該微型 散熱基板1。藉此,該微型散熱基板丨及微型驅熱風機2 不萬經由額外設置其他組裝構件〔例如:螺絲、彈性件或 扣件等〕即可快速組裝形成該微型散熱模組,其有助於簡 化組裝程序及提升組裝效率,同時亦具有良好之組裝可靠 度,以進一步應用於該微型電子裝置上。 請再參照第2圖所示,當驅動本發明第一實施例進行 散熱動作時’由於該微型驅熱風機2之入風口 21軸向外露 於該微型散熱基板1之頂部,且該微型驅熱風機2之出風 口 22亦對應該氣流通道12之一端,使得該微型驅熱風機 2可經由該入風口 21吸入一外部氣流,並經由該出風口 22 朝該Uitaf 12之-端送㈣氣流,以迫使該氣流通道 12上之受熱空氣自該氣流通道12之另一端離開。另外, 該散熱鰭片π之頂部較佳係不低於該出風口 22之頂緣, 以相對提升該微型散熱模組之熱交換效率。 清參照第3圖所示’其揭示本發明第二實施例之微型 散熱模組。相較於第—實施例,第二實施例之微型散熱基 板1係進-步於該微型散熱基板 1之一端邊一體成型向上 ’f折形成該第二定位部14。該定位空間17形成於該第一 及第二定位部13、14之間,且該第—及第二定位部13、 ——10 — 1314033 耵.11.19第96102482號專利說明書、申請專利範園及圓式修正本。 Η間之距離略小於賴翻熱職2之長度 及第,位部13>14穩_將該微型驅熱風機^央^定位 於該定位空間17内,同時該微型驅熱風機2之出風口 22 對應朝向職流通道12之__端,使得本發財實可有效 升組裝效率,同時亦具有良好之組裝可靠度。 说,參照第4圖所示,其揭示本發明第三實施例之微型 t熱模組。相較於第二實蘭,第三實_ =鄰接該定位空間17之三個端邊上,係分別一體成、; =上f折形成該第二定位部14、第三定位部15及―第四 =立部16。該第二、第三及細定位部14、i5、16均選 抵擇凸塊構造,且其三者之寬度及高度均選擇小於 ,微型驅熱風機2之高度及寬度。該定位空間17則圍繞形 成於該第一、第二、第三及第四定位部13、ΐ4、ΐ5、Μ 該定位空間17之長度及,或寬度略小於該微型驅熱 =2之長度及寬度^藉此,當該微迦熱風機2組裝於 ^定位空間17内之後,該第―、第二、第三及第四定位部 、14、15、16係分別夾壓該微_減機2之外周邊, 2免該微型驅熱風機2任意脫離該微型散熱基座卜使 2發明確實可有效提升組裝效率及可靠度,並簡化組裝 構件。 二“、、第5圖所示’其揭示本發明第四實施例之微型 ,’、、模、I。條於第二實施例’第四實施例之微型驅熱風 兮―係^ —軸向人風且軸向出風之軸流式驅熱風機,且 h弟一及第二定位部14、15選擇對應凸^於該微型散熱基 1314033 97.^9第_2482號專利說明書、申請專利範圍及圖式修正本。 板1之端邊位置。另外,該第二、第三定位部14、15與該 第疋位13之間係分別形成一導槽a,該導槽巳可精確 導引該微型驅熱風機2迫^該定位空間17。該定位空間17 形成於該第-、第二及第三定位部13、14、15之間。再者 ,該微型驅熱風機2之入風口 21〔或出風口 22〕係外露於 該第二、第三定位部14、15間之開口〔未標示〕,而該微 型驅熱風機2之出風口 22〔或入風口 21〕則對應各該氣流 H 2之&藉由該第一定位部13抵壓該微型驅熱風 機2之一侧面,同時該第二及第三定位部14、15亦夾^該 微型驅熱風機2之另一侧面’進而有效提升本發明之組裝 效率及組裝精確度。 μ > 第6圖所示’其揭示本發明第五實施例之微型 散熱模組。相較於第四實施例,第五實施例之第二及第三 疋位部14、15係自該最外侧之二散熱鯖片11的-端沿著 該微型散熱基板1之側邊分別延伸形成,且該第二衣第三 定位部14、丨5分別設有該導槽a。另外,該微型驅熱風機 ^相對於該第二及第三定位部14、15之二侧面係分別對應 认置一導引凸塊b ’其用以對位迫入該導槽a内,以便該 導槽a導引該微型驅熱風機2組裝定位於該定位空間17内 ,進一步提升本發明之組裝效率及組裝精確度。 如上所述,相較於第】圖之習用散熱模組必須藉由分 元件8及數個組裝孔73以達成-散熱風扇 心疋位結合於—散熱基板7之目的,但卻導致習用 熱模組難以應用於該微型電子裝置上,且需額外利用組裝 —12 — 1314033 97.11.19第96102482號專利說明書、申請專利範圍及圖式修正本β 元件之繁雜組裝構件等缺點,第2圖之本發明藉由在該微 型散熱基板1上形成該第一、第二及第三定位部13、14、 15 ’並利用該第一、第二及第三定位部13、14、15將該微 型驅熱風機2穩固的夾壓定位於該微型散熱基板1上。另 外,該微型驅熱風機2之扇輪的旋轉面積必須小於16 cm2 〔平方公分〕,藉此使得本發明可應用於微型化之電子裝 置上,且不需藉由設置任何組裝元件,具有簡化組裝構件 及提升組裝可靠度、品質之功效。 雖然本發明已利用上述較佳實施例揭示,然其並非用 以限定本發明’任何熟習此技藝者在不脫離本發明之精神 和範圍之内,相對上述實施例進行各種更動與修改仍屬本 發明所保護之技術範疇’因此本發明之保護範圍當視後附 之申請專利範圍所界定者為準。 —13 — 1314033 97.11.19第96102482號專利說明書、申請專利範圍及圖式修正本β 【圖式簡單說明】 第1圖:習用散熱模組之分解立體圖。 第2圖:本發明第一實施例之微型散熱模組之分解立體 圖。 第3圖:本發明第二實施例之微型散熱模組之分解立體 圖。 第4圖:本發明第三實施例之微型散熱模組之分解立體 圖。 第5圖:本發明第四實施例之微型散熱模組之分解立體 圖。. 第6圖:本發明第五實施例之微型散熱模組之分解立體 圖0 【主要元件符號說明】 1 微型散熱基板 11 散熱鳍片 12 氣流通道 13 第一定位部 14 第二定位部 141 夾持片 15 第三定位部 151 夾持片 16 第四定位部 17 定位空間 2 微型驅熱風機 20 殼體 21 入風口 22 出風口 23 扇輪 7 散熱基板 71 散熱鰭片 72 散熱槽道 73 組裝孔 8 固定元件 —14 i3iim㈣匪號專侧書、辦删賴修正本。 81 扣合部 82 抵撐肩部 83 復位彈簧 9 散熱風扇 91 通孔 a 導槽 b 導引凸塊 —1531, the first 482 patent specification, the scope of application for patents and the revised version of the schema. The invention relates to a micro heat dissipation module, and more particularly to providing at least two positioning portions on a micro heat dissipation substrate, and the positioning portion is used to heat a micro heat. Stabilization_Combined on the micro-thermal substrate micro-diffusion f prior art] For the conventional heat-dissipating module, please refer to the first! As shown, it comprises a heat sink substrate 7, a plurality of solid elements 8 and a heat sink fan 9. One surface of the heat dissipation substrate 7 is provided with a plurality of heat dissipation fins 71 and a plurality of heat dissipation channels 72, and the heat dissipation channels 72 are formed between the adjacent heat dissipation fins 71. In addition, a plurality of stages of holes are formed in the bottom surface of the heat dissipation channel 72 for the fixed element 8 to be correspondingly set. The fixing member 8 is provided with a fastening portion, an abutment shoulder portion 82 and a return spring 83. The fastening portion 81 is formed at one end of the fixing member 8 and is selected from an inverted tapered structure, and a slit (not shown) is opened in the center of the fastening portion μ to provide an elastic deformation space. The abutment shoulder 82 is formed at the other end of the fixing member 8. The reset bomb! 83 corresponds to the (four) fixed element 8, and its end is abutted against the resisting portion 82. The corner position of the heat radiating fan 9 is provided with a plurality of through holes 91 corresponding to the assembly hole 73. When the heat dissipating fan 9 is assembled on the heat dissipating substrate 7, firstly, the through holes 91 of the 5H cooling fan 9 are respectively located on the heat dissipating substrate 7 and the hole 73, and then the fastening portion of the fixing member 8 81 is forced into the through hole 91 by the reverse tapered shape and the corresponding elasticity of the opening, until the engaging portion 81 passes the patent specification, the patent scope and the round revision of the patent No. 96102482. . After the hole 91 and the assembly hole 73, the fastening portion 81 is immediately elastically restored to return to its original position, and is slid on the bottom surface of the heat dissipation substrate 7 via the bottom end of the fastening portion. At this time, the return spring 83 of the cymbal member 8 generates an elastic reset bias so that the bottom end of the engaging portion 81 is firmly fixed against the bottom surface of the substrate 7. Thereby, the heat radiating fan 9 is used to drive off the hot air in the heat dissipating channel 72, thereby improving the heat dissipation efficiency of the heat dissipating substrate 7. Generally, the heat dissipation module is often applied to an electronic device (not shown, for example, a computer chip or a microprocessor). As technology advances with each passing day, the size of the electronic device is directed toward miniaturization, making the electronic device more and more precise and small. As a result, the size and volume of the heat dissipation module must be relatively small. however. The conventional heat dissipation module has the following disadvantages. For example, the conventional heat dissipation module must be provided with the fixing member 8 and the hole 73 to achieve a stable fixed position. However, when the size of the heat dissipation module is small to a certain extent, it is not easy to open the assembly hole 73 of the heat dissipation substrate 7 enough to accommodate the fixing component 8, and it is also difficult to manufacture the fixing component 8 of a small size, resulting in a conventional heat dissipation mode. The group is difficult to apply to the miniaturized electronic device. For the above reasons, it is necessary to further improve the above conventional heat dissipation module. In view of the above, the present invention improves the above-mentioned disadvantages by forming at least two portions on a micro-Wei heat substrate, and positioning the portion to securely clamp a micro-drive heat fan to the micro heat dissipation. On the substrate. In addition, the rotating area of the fan wheel of one of the micro-driven heat fans is less than 1.6 cm 2 (cm 2 ), thereby reducing the size of the micro heat-dissipating module, whereby the invention can be applied to the miniaturized electronic device and has Simplify the group 褒 component (4). For the lang 2nd patent specification, t request the patent _ type revision. And improve the efficiency of assembly. SUMMARY OF THE INVENTION The main object of the present invention is to provide a micro heat dissipation module by forming at least two positioning portions on a micro heat dissipation substrate, and using the positioning portion to firmly bond the micro heat drive fan The micro heat dissipating substrate has the effect of simplifying the assembly of components and improving assembly reliability and quality without providing any assembly components. The secondary object of the present invention is to provide a micro heat dissipating module, wherein a micro-heating fan-fan wheel has a rotating area of less than 16 cm 2 [cm 2 ], thereby reducing the size of the micro heat dissipating module, so that the present invention has Applied to the efficacy of miniaturized products. The micro heat dissipation module according to the present invention comprises a micro heat dissipation substrate and a micro heat drive fan. The micro heat dissipating substrate has a positioning space, an air flow channel, a plurality of heat dissipating fins, and at least two positioning portions. The positioning space, the air flow channel, the heat dissipating fins and the positioning portion are all disposed on the surface of the micro heat dissipating substrate. The flow channel is formed between the two adjacent heat dissipation fins, the air flow channel has two ends and extends from one end to the other end in a direction parallel to the surface, and the plurality of heat dissipation fins are adjacent to the positioning space One of the at least two positioning portions is formed together, and the positioning space is formed between at least two positioning portions of the micro heat dissipation substrate. The micro-driven heat blower is provided with an air outlet, an air inlet and a wheel, and the rotating area of the fan wheel is less than 1.6 square centimeter. The micro-heating fan is clamped to the miniature by the positioning portion of the micro heat-dissipating substrate. In the positioning space of the heat dissipating substrate, one of the air outlet and the air inlet is selected to be aligned, oriented, and in close proximity to the heat dissipating fin, the patent specification, the patent application scope and the schema revision. The positioning portion and the air flow channel are adjacent to one end of the positioning space. The above and other objects, features, and advantages of the present invention will become more <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt; As shown in the figure, the micro heat dissipation module of the first embodiment of the present invention comprises a micro heat dissipation substrate 1 and a micro heat drive fan 2, and the micro heat drive fan 2 is correspondingly positioned on the micro heat dissipation substrate 1 to form a miniature. Cooling module [not labeled]. Referring to FIG. 2 again, the micro heat dissipation substrate 1 of the first embodiment of the present invention is made of a metal or an alloy having high thermal conductivity, such as aluminum, copper, gold, silver or alloys thereof, and the like. The heat dissipation substrate 丨 is preferably slightly flexible. The micro heat dissipation substrate 1 is provided with a plurality of heat dissipation fins u, at least one air flow channel 12, at least two positioning portions, and a positioning space 17. The heat dissipation fins 11 are arranged to be aligned with the micro heat dissipation substrate i. A surface 'and each of the air flow channels 12 is formed between the two adjacent heat dissipation fins 11. The heat dissipation fins 1 , the air flow channel 12 , the positioning portion and the positioning space are all disposed on one surface of the micro heat dissipation substrate. The heat dissipating fins 11 and the air flow passages 12 are used to increase the heat exchange area of the micro heat dissipating substrate to quickly dissipate the heat absorbed by the micro heat dissipating substrate i and improve the heat dissipating efficiency. In addition, the micro heat dissipation substrate 1 of the first embodiment of the present invention is provided with a first positioning portion 13, a second positioning portion 14, and a third positioning portion 15, and the side edges of the heat dissipation tabs 11 are combined to form a resistance. The face is further described as the patent specification, the patent application scope and the schema revision of the 1314033 37_11.19. A positioning portion 13. One end of the outermost two fins u extend along the side of the micro heat dissipation substrate 1 to form the second and third positioning portions 14 and 15, and the second and third positioning portions 14 and 15 The top portions are also bent inwardly toward each other to form a holding piece 141, 151. The positioning space 17 is formed between the first, second, and third positioning portions 13, 14, 15 and the holding pieces hi, 151. Referring to FIG. 2 again, the micro-driven heat blower 2 of the first embodiment of the present invention can be selected from an axial wind-in and radial-flow blast-type heat-driven fan and an axial air inlet and shaft. The axially driven heat-dissipating fan to the air outlet, the micro-driven heat-dissipating fan 2 of the present embodiment is selected as a blast-type heat-driven fan that is axially ventilated and radially ventilated. The micro-heating fan 2 is provided with a casing 20, an air inlet 21, an air outlet 22 and a fan wheel 23. The housing 20 has a housing space (not shown) inside. The air inlet 21 is axially opened at the top of the casing 2〇; the air outlet 22 is selected to be radially open on one side of the casing 20, and the air outlet 22 corresponds to one end of the airflow passage 12. The fan wheel 23 is rotatably disposed in the accommodating space, and the rotation area thereof is selected to be less than 1.6 cm 2 (cm 2 ) to reduce the size of the micro heat dissipation module. Further, the micro heat dissipation module is applied to a miniature Electronic devices (eg, microcomputers, mini PDAs, mobile phones, etc.). • Referring to FIG. 2 again, when the first embodiment of the present invention is assembled, 'the first is to have the flexibility of the micro heat dissipation substrate 1 so that the micro heat drive fan 2 can along the micro heat dissipation substrate. The second and third positioning portions 14 and 15 of the first and third positioning portions 14 and 15 and the inner wall surfaces of the holding pieces 141 and 151 are forced into the positioning space 17. Since the width and height of the positioning space 17 are slightly smaller than the width and height of the heat-driven fan 2 of the patent specification, the patent application scope and the drawing, the micro-heating fan 2 is forced. After entering the positioning space 17, the first and third positioning portions 14 and 15 and the clamping pieces 141 and 151 are also stabilized, except that one end of the micro-heating fan 2 abuts against the first positioning portion 13. The micro-heating fan 2 is pinched and positioned in the positioning space 17, and the micro-heating fan 2 is prevented from being detached from the micro-heat-dissipating substrate 1 arbitrarily. Therefore, the micro heat dissipation substrate 丨 and the micro heat drive fan 2 can be quickly assembled to form the micro heat dissipation module by additionally providing other assembly members (for example, screws, elastic members, fasteners, etc.), which contributes to simplification. The assembly process and the improvement of assembly efficiency, as well as good assembly reliability, are further applied to the microelectronic device. Referring to FIG. 2 again, when the first embodiment of the present invention is driven to perform a heat dissipation operation, 'the air inlet 21 of the micro-heating fan 2 is axially exposed on the top of the micro heat-dissipating substrate 1, and the micro-driven hot air The air outlet 22 of the machine 2 also corresponds to one end of the air flow passage 12, so that the micro-driven heat blower 2 can suck an external air flow through the air inlet 21, and send (four) airflow to the Uitaf 12-end via the air outlet 22, The forced air on the air flow passage 12 is forced to exit from the other end of the air flow passage 12. In addition, the top of the heat dissipation fin π is preferably not lower than the top edge of the air outlet 22 to relatively improve the heat exchange efficiency of the micro heat dissipation module. Referring to Fig. 3, a micro heat dissipation module according to a second embodiment of the present invention is disclosed. Compared with the first embodiment, the micro heat dissipation substrate 1 of the second embodiment is formed integrally with one end edge of the micro heat dissipation substrate 1 to form the second positioning portion 14. The positioning space 17 is formed between the first and second positioning portions 13 and 14, and the first and second positioning portions 13 and 10-1314033 耵.11.19, the patent specification No. 96102482, the patent application garden and Round revision. The distance between the turns is slightly smaller than the length of the hot work 2 and the first position 13 > 14 stable _ the micro heat drive fan ^ center ^ is positioned in the positioning space 17, while the air outlet of the micro heat drive 2 22 corresponds to the __ end of the service flow channel 12, so that the financial development can effectively improve assembly efficiency, and also has good assembly reliability. Referring to Fig. 4, there is disclosed a micro t thermal module according to a third embodiment of the present invention. Compared with the second real blue, the third real_= adjacent to the three end sides of the positioning space 17 are integrally formed; the upper f is folded to form the second positioning portion 14, the third positioning portion 15 and Fourth = Standing 16. The second, third, and fine positioning portions 14, i5, and 16 are all selected to have a bump structure, and the width and height of the three are selected to be smaller than the height and width of the micro-thermal blower 2. The positioning space 17 is formed around the first, second, third, and fourth positioning portions 13, ΐ4, ΐ5, 长度, the length of the positioning space 17, and the width is slightly smaller than the length of the micro heat drive = 2 Width ^ thereby, after the micro-heater 2 is assembled in the positioning space 17, the first, second, third and fourth positioning portions, 14, 15, 16 respectively clamp the micro-reduction machine 2, the periphery, 2 free of the micro-heating fan 2 arbitrarily detached from the micro-heat-dissipation pedestal. 2 The invention can effectively improve the assembly efficiency and reliability, and simplify the assembly of components. 2, and 5, which show the micro, ', , and I, according to the fourth embodiment of the present invention, in the second embodiment, the fourth embodiment of the micro-driven hot air 兮 - system - axial An axial-flow type heat-driven fan that is windy and axially ventilated, and the second and second positioning portions 14 and 15 of the second and second positioning portions 14 and 15 are selected to be corresponding to the micro heat-dissipating base 1314033 97. Scope and schema correction. The position of the end of the plate 1. In addition, a guide groove a is formed between the second and third positioning portions 14, 15 and the third position 13, and the guide groove can be accurately guided. The micro-heating fan 2 is forced to the positioning space 17. The positioning space 17 is formed between the first, second and third positioning portions 13, 14, 15. Further, the micro-driven heat fan 2 enters The tuyere 21 (or the air outlet 22) is an opening (not shown) exposed between the second and third positioning portions 14 and 15, and the air outlet 22 (or the air inlet 21) of the micro-driven heat fan 2 corresponds to each The airflow H 2 is pressed against the side of the micro-heating fan 2 by the first positioning portion 13 while the second and third positioning portions 14 and 15 are also ^The other side of the micro-heating fan 2' is effective to improve the assembly efficiency and assembly accuracy of the present invention. μ > Figure 6 shows a micro-heat-dissipation module according to a fifth embodiment of the present invention. In the fourth embodiment, the second and third clamping portions 14 and 15 of the fifth embodiment are respectively formed from the ends of the outermost two heat dissipating fins 11 along the sides of the micro heat dissipating substrate 1 . The second positioning portion 14 and the second portion of the second positioning portion 14 and the second positioning portion 14 are respectively corresponding to the two side portions of the second and third positioning portions 14 and 15 respectively. A guiding protrusion b' is used for aligning into the guiding slot a, so that the guiding slot a guides the micro-heating fan 2 to be assembled and positioned in the positioning space 17, further improving the assembly efficiency of the invention and Assembly accuracy. As described above, the conventional heat dissipation module of the first embodiment must be coupled to the heat dissipating substrate 7 by means of the sub-element 8 and the plurality of assembly holes 73. Leading to the use of conventional thermal modules is difficult to apply to the microelectronic device, and additional benefits Assembly of the present invention, the patent specification, the patent application, and the drawings, the simplification of the complicated assembly of the beta component, and the like, the second invention of the present invention is formed on the micro heat dissipation substrate 1 And the second and third positioning portions 13 , 14 , 15 ′ and the first, second and third positioning portions 13 , 14 , 15 are used to stably position the micro heat-dissipating fan 2 on the micro heat dissipation substrate 1 In addition, the rotating area of the fan wheel of the micro-driven heat fan 2 must be less than 16 cm 2 [cm 2 ], thereby making the present invention applicable to miniaturized electronic devices without setting any assembly components. It has the effect of simplifying the assembly of components and improving the reliability and quality of assembly. The present invention has been disclosed in the above-described preferred embodiments, and it is not intended to limit the invention. It is intended that the present invention may be practiced without departing from the spirit and scope of the invention. The technical scope of the invention is protected by the scope of the invention as defined by the appended claims. —13 — 1314033 97.11.19 Patent specification No. 96102482, the scope of application and the revision of the figure β [Simplified description of the drawing] Fig. 1: An exploded perspective view of the conventional heat dissipation module. Fig. 2 is an exploded perspective view showing the micro heat dissipation module of the first embodiment of the present invention. Fig. 3 is an exploded perspective view showing the micro heat dissipation module of the second embodiment of the present invention. Fig. 4 is an exploded perspective view showing the micro heat dissipation module of the third embodiment of the present invention. Fig. 5 is an exploded perspective view showing the micro heat dissipation module of the fourth embodiment of the present invention. Fig. 6 is an exploded perspective view of a micro heat dissipation module according to a fifth embodiment of the present invention. [Description of main components] 1 micro heat dissipation substrate 11 heat dissipation fin 12 air flow passage 13 first positioning portion 14 second positioning portion 141 Sheet 15 Third positioning portion 151 Holding piece 16 Fourth positioning portion 17 Positioning space 2 Micro heat drive fan 20 Housing 21 Air inlet 22 Air outlet 23 Fan wheel 7 Heat sink substrate 71 Heat sink fin 72 Heat sink channel 73 Assembly hole 8 Fixed components - 14 i3iim (four) nickname book, do not modify the book. 81 Snaps 82 Retaining shoulders 83 Reset spring 9 Cooling fan 91 Through hole a Guide groove b Guide projection —15